Multi-pass cooling drip cap

ABSTRACT

A device may include an inlet end having a first opening configured to connect to an atomizer device. The device may include an outlet end having a second opening configured to permit a user to inhale a vapor generated by the atomizer device. The device may include a first baffle configured to direct a flow of the vapor towards a first internal surface of the device. The device may include the first internal surface. The device may include a second baffle configured to direct the flow of the vapor towards a second internal surface of the device. The device may include the second internal surface configured to impede the flow of the vapor and cause the flow of the vapor to be directed towards the outlet end of the device.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority under 35 U.S.C. § 119 to U.S.Provisional Application No. 62/432,834, filed on Dec. 12, 2016, thecontents of which are incorporated by reference in their entirety.

BACKGROUND

A vaporizer is a device that is capable of vaporizing materials havingdifferent viscosities to generate vapor. In some cases, an atomizer, ofa vaporizer, heats a material to generate vapor that is then inhaled bya user. The temperature of the vapor can affect usability and/orefficacy of the vaporizer.

SUMMARY

According to some possible implementations, a device may include aninlet end having a first opening that is configured to connect to anatomizer device. The device may include an outlet end having a secondopening that is configured to permit a user to inhale a vapor generatedby the atomizer device. The device may include a first baffle that isconfigured to direct a flow of the vapor towards a first internalsurface of the device in a first direction towards the outlet end andaway from the inlet end. The device may include the first internalsurface that is configured to impede the flow of the vapor in the firstdirection. The device may include a second baffle that is configured todirect the flow of the vapor towards a second internal surface of thedevice in a second direction towards the inlet end and away from theoutlet end. The device may include the second internal surface that isconfigured to impede the flow of the vapor in the second direction andcause the flow of the vapor to be directed towards the outlet end of thedevice. The second baffle, and/or a surface of the second baffle, may beconfigured at an angle in order to increase the opening size along thesurface and expand the vapor. A greater width of the chamber of thedevice may be near the outlet end of the device.

According to some possible implementations, a device may include aninlet end having a first opening. A flow of vapor, generated by anatomizer device, may enter the inlet end of the device via the firstopening. The device may include a first baffle that is configured todirect the flow of the vapor towards a first internal surface of thedevice in a first direction towards an outlet end of the device and awayfrom the inlet end of the device. The flow of the vapor may be directedby the first baffle based on entering the inlet end of the device. Thedevice may include the first internal surface that is configured toimpede the flow of the vapor in the first direction. The flow of thevapor may be impeded by the first internal surface based on beingdirected by the first baffle. The device may include a second bafflethat is configured to direct the flow of the vapor in a second directiontowards the inlet end of the device and away from the outlet end of thedevice. The flow of the vapor may be directed by the second baffle basedon being impeded by the first internal surface. The device may include asecond internal surface that is configured to impede the flow of thevapor in the second direction. The flow of the vapor may be impeded bythe second internal surface of the device based on being directed by thesecond baffle. The flow of the vapor may be directed in the firstdirection based on being impeded by the second internal surface. Thedevice may include the outlet end having a second opening. The flow ofthe vapor may exit the outlet end of the device via the second openingbased on being directed in the first direction.

According to some possible implementations, a cap for a vaporizer devicemay include an inlet that is configured to permit a flow of a vapor,generated by the vaporizer device, to enter the cap. The cap for thevaporizer device may include a set of internal surfaces that isconfigured to impede the flow of the vapor. The cap for the vaporizerdevice may include a set of baffles that is configured to direct theflow of the vapor towards the set of internal surfaces and towards anoutlet of the cap. The cap for the vaporizer device may include theoutlet that is configured to permit the flow of the vapor to exit thecap.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram of an example vaporizer device described herein;

FIGS. 2A and 2B are diagrams of a cross section of a cooling devicedescribed herein;

FIG. 3 is a bottom view of the cooling device described herein; and

FIG. 4 is a top view of the cooling device described herein.

DETAILED DESCRIPTION

The following detailed description of example implementations refers tothe accompanying drawings. The same reference numbers in differentdrawings may identify the same or similar elements.

A user may use a vaporizer device to inhale vapor generated by thevaporizer device. For example, the vaporizer device may heat a solutionto generate vapor that can then be inhaled by the user. In some cases,the vaporizer device may generate vapor having a temperature that causesthe inhalation process to be unpleasant for the user, that causes theinhalation process to be impossible for the user, and/or the like. As aresult, the usability and/or efficacy of the vaporizer device may benegatively affected.

Some implementations described herein provide a cooling device thatpermits a temperature of a flow of vapor, generated by an atomizerdevice of a vaporizer device, to be reduced during operation of thevaporizer device. For example, and as described elsewhere herein, thecooling device may include a set of baffles and a set of internalstructures that are configured to direct and/or impede a flow of vaporto permit the flow of vapor to experience a reduction in temperature asthe flow of vapor is disposed within the cooling device. In this way,some implementations described herein improve a user experienceassociated with vaporizer devices, improve usability of vaporizerdevices, improve practicality of vaporizer devices, improve efficacy ofvaporizer devices, reduce a need for water-cooling of the vapor, and/orthe like.

FIG. 1 is a diagram of an example vaporizer device 100 described herein.As shown in FIG. 1, vaporizer device 100 may include a mouthpiece 102, acooling device 104, an atomizer device 106, and a battery 108. Vaporizerdevice 100 may include a device that is configured to vaporize amaterial to permit a user to inhale vapor associated with the material.For example, vaporizer device 100 may include a vaporizer, a nebulizer,an electronic cigarette, and/or any other type of inhalation device.

The material may include a solution, an oil, a liquid, a solid, amixture, and/or the like. For example, the ingredient may include one ormore of propylene glycol, glycerol, water, nicotine, a flavoring, achemical, and/or the like. While implementations herein describevaporization of a material to generate a vapor, it should be understoodthat implementations described herein are applicable to other types ofdevices that generate other types of substances such as aerosols, gases,mist, and/or the like.

Mouthpiece 102 may include a device that is configured to permit a userto inhale vapor generated by vaporizer device 100. For example, a mouthof the user may establish direct or indirect contact with mouthpiece 102to permit the user to inhale vapor generated by vaporizer device 100.Mouthpiece 102 may be comprised of a material such as polycarbonateplastic, polyethylene plastic, polypropylene plastic, polystyreneplastic, an aluminum alloy, a titanium alloy, a carbon fiber plastic,glass, ceramic, and/or the like.

Cooling device 104 includes a device that is configured to cause areduction in temperature of vapor generated by vaporizer device 100. Forexample, vapor generated by atomizer device 106 may enter cooling device104 via an inlet end, may experience a reduction in temperature whilebeing disposed within cooling device 104, and may exit cooling device104 via an outlet end.

Cooling device 104 may be comprised of a material such as polycarbonateplastic, polyethylene plastic, polypropylene plastic, polystyreneplastic, an aluminum alloy, a titanium alloy, a carbon fiber plastic,glass, ceramic, and/or the like. Further, cooling device 104 may becomprised of any type of material that is associated with thermalconductivity properties that permit a reduction in temperature of vaporthat passes through cooling device 104. For example, cooling device 104may be comprised of any type of material, or a set of materials, thatpermits heat of vapor to be absorbed and/or dissipated by cooling device104. Cooling device 104 may be referred to as a cooling device, adevice, a cap, a cooling cap, a cooling drip cap, a multi-pass coolingdrip cap, a multi-pass device, and/or the like.

Atomizer device 106 may include a device that is configured to vaporizea material to generate vapor. For example, atomizer device 106 mayinclude an atomizer, a cartomizer, a clearomizer, and/or the like.Atomizer device 106 may include a set of coils (e.g., a single coil, twocoils, four coils, etc.) connected to a positive terminal and a negativeterminal of battery 108. For example, atomizer device 106 may include atop coil, a top feeding coil, a bottom coil, and/or the like. The set ofcoils may be comprised of stainless steel, nickel, and/or the like.

Battery 108 includes a device that is configured to provide electricpower to atomizer device 106. For example, battery 108 may include anickel-cadmium (NiCd) battery, a nickel-metal hydride (NiMH) battery, alithium-ion (Li-ion) battery, and/or the like.

During operation of vaporizer device 100, battery 108 may provideelectric power to atomizer device 106. Atomizer device 106 (e.g., theset of coils of atomizer device 106) may generate heat which causesvaporization of a material. The vapor may pass through cooling device104 and mouthpiece 102, thereby permitting a user to inhale the vaporgenerated by atomizer device 106.

Vaporizer device 100 may be substantially cylindrical in shape. As anon-limiting example, vaporizer device 100 may include a diameter offourteen (14) millimeters (mm) and a length of one hundred and fifteen(115) mm. Continuing the example, mouthpiece 102 may include a diameterof fourteen (14) mm, and a length of fifteen (15) mm. Continuing theexample, cooling device 104 may include a diameter of fourteen (14) mm,and a length of twenty two (22) mm. Continuing the example, atomizerdevice 106, and a suitable housing, may include a diameter of fourteen(14) mm, and a length of nineteen and three quarters (19.75) mm.Continuing the example, battery 108, and a suitable housing, may includea diameter of fourteen (14) mm, and a length of fifty two and a quarter(52.25) mm.

While an example shape and example dimensions are shown and/or describedin association with FIG. 1, it should be understood that implementationsdescribed herein are applicable to other vaporizer devices 100 includingdifferent shapes, configurations, devices, and/or dimensions.

Although FIG. 1 shows an example vaporizer device 100, vaporizer device100 may include additional devices, fewer devices, different devices, ordifferently arranged devices than those depicted in FIG. 1.Additionally, or alternatively, two or more devices of vaporizer device100 may be combined as a single device.

FIGS. 2A and 2B are diagrams of a cross section 200 of cooling device104. As shown in FIG. 2A, cooling device 104 may include an inlet end202, an outlet end 204, a first baffle 206, a first internal surface208, a second baffle 210, a second internal surface 212, an internalopening 214, and a sidewall 216.

As shown in FIG. 2A, inlet end 202 may include an opening that isconfigured to connect to atomizer device 106. For example, inlet end 202may include a connection mechanism to permit connection of coolingdevice 104 to atomizer device 106. The connection mechanism may includea threaded portion to permit atomizer device 106 to be connected tocooling device 104. Alternatively, the connection mechanism may includea set of O-rings, a toric joint, an internal portion to permit apress-fit and/or an interference fit, a seal, an internal coating,and/or the like.

As further shown in FIG. 2A, outlet end 204 may include an opening thatis configured to connect to mouthpiece 102. For example, outlet end 204may include a connection mechanism to permit connection of coolingdevice 104 to mouthpiece 102. Referring to FIG. 2B, and as a particularexample, outlet end 204 may include an O-ring 218 that is configured tomate with a notch 220 of mouthpiece 102. As further shown in FIG. 2B, aportion 222 of mouthpiece 102 may include an outer diameter that issmaller than an inner diameter of sidewall 216 of cooling device 104,thereby permitting portion 222 of mouthpiece 102 to be inserted intocooling device 104. In this way, O-ring 218 of cooling device 104 maymate with notch 220 to connect cooling device 104 and mouthpiece 102.Alternatively, mouthpiece 102 may connect to cooling device 104 viaanother type of connection mechanism.

As further shown in FIG. 2A, first baffle 206 may include a structurethat is configured to direct a flow of vapor. As further shown in FIG.2B, first baffle 206 may include a first inlet edge 206 a, a firstoutlet edge 206 b, a first inner surface 206 c, and a first outersurface 206 d.

First baffle 206 may include a frustoconical shape, a conical shape, apyramidal shape, and/or the like. For example, first baffle 206 maytaper inwardly from inlet end 202 towards outlet end 204. Alternatively,first baffle 206 may include a substantially cylindrical shape, may nottaper inwardly, and/or may include another type of shape.

As further shown in FIG. 2A, first internal surface 208 may include astructure that is configured to impede a flow of vapor. For example,first internal surface 208 may include a substantially horizontallydisposed internal surface that is configured to impede a flow of vapor.As further shown in FIG. 2B, first internal surface 208 may include afirst bottom surface 208 a and a first top surface 208 b.

As further shown in FIG. 2A, second baffle 210 may include a structurethat is configured to direct a flow of vapor. As further shown in FIG.2B, second baffle 210 may include a second inlet edge 210 a, a secondoutlet edge 210 b, a second inner surface 210 c, and a second outersurface 210 d.

Second baffle 210 may include a frustoconical shape, a conical shape, apyramidal shape, and/or the like. For example, second baffle 210 maytaper outwardly from outlet end 204 towards inlet end 202.Alternatively, second baffle 210 may include a substantially cylindricalshape, may not taper inwardly, and/or may include another type of shape.

First baffle 206 and second baffle 210 may include corresponding shapes.For example, and as shown in FIGS. 2A and 2B, first baffle 206 andsecond baffle 210 may both include a frustoconical shape. Alternatively,first baffle 206 and second baffle 210 may include different shapes thanas compared to one another. For example, first baffle 206 may include afrustonical shape whereas second baffle 210 may include a circularshape. It should be understood that many other types of configurationsare possible.

As further shown in FIG. 2A, second internal surface 212 may include astructure that is configured to impede a flow of vapor. For example,second internal surface 212 may include a substantially horizontallydisposed internal surface that is configured to impede a flow of vapor.As further shown in FIG. 2B, second internal surface 212 may include asecond bottom surface 212 a and a second top surface 212 b.

As further shown in FIG. 2A, internal opening 214 may include astructure that is configured to permit a flow of vapor to pass throughcooling device 104 from inlet end 202 to outlet end 204. First internalsurface 208 may include a set of internal openings 214 that permit aflow of vapor to pass through cooling device 104. For example, firstinternal surface 208 may include a single internal opening 214, twointernal openings 214, five internal openings 214, etc.

During operation of vaporizer device 100, a user may interact withvaporizer device 100 to cause atomizer device 106 to generate vapor.Additionally, the user may interact with mouthpiece 102 to generatesuction to cause a flow of vapor from atomizer device 106 towardsmouthpiece 102.

The flow of vapor may enter cooling device 104 via inlet end 202 ofcooling device 104. For example, the flow of vapor may flow in a firstdirection towards outlet end 204 and away from inlet end 202. The vapor,when entering cooling device 104, may include a temperature that issubstantially the same temperature as when atomizer device 106 generatedthe vapor.

First baffle 206 may direct the flow of vapor towards first internalsurface 208 based on the flow of vapor entering cooling device 104 viainlet end 202. For example, first inner surface 206 c of first baffle206 may direct the flow of vapor in the first direction towards firstbottom surface 208 a of first internal surface 208. Additionally, secondbottom surface 212 a of second internal surface 212 may direct the flowof vapor towards first bottom surface 208 a of first internal surface208 based on the flow of vapor entering cooling device 104 via inlet end202.

First internal surface 208 may impede the flow of vapor based on firstbaffle 206 directing the flow of vapor towards first internal surface208. For example, first bottom surface 208 a of first internal surface208 may impede the flow of vapor, thereby reducing a velocity of theflow of vapor in the first direction. In this way, some implementationsdescribed herein increase an amount of time, measured from a first timeat which the flow of vapor exits atomizer device 106 and a second timeat which the flow of vapor enters mouthpiece 102, than as compared tosituations where the flow of vapor is relatively unimpeded. Byincreasing the amount of time, some implementations described hereinpermit a reduction in temperature of the vapor.

First baffle 206 and second baffle 210 may direct the flow of vaportowards second internal surface 212 based on first internal surface 208impeding the flow of vapor. For example, first outer surface 206 d offirst baffle 206 and second inner surface 210 c of second baffle 210 maydirect the flow of vapor towards second top surface 212 b of secondinternal surface 212 based on first bottom surface 208 a of firstinternal surface 208 impeding the flow of vapor in the first direction.Additionally, first baffle 206 and second baffle 210 may direct the flowof vapor in a second direction towards inlet end 202 and away fromoutlet end 204. Put another way, the flow of vapor may flow in thesecond direction between first outer surface 206 d of first baffle 206and second inner surface 210c of second baffle 210.

In this way, some implementations described herein increase an amount ofsurface area of thermally conductive material that contacts the flow ofvapor. Additionally, in this way, some implementations described hereinpermit a reduction in temperature of the vapor by permitting heat to beabsorbed and/or dissipated by first baffle 206, first internal surface208, second baffle 210, and/or second internal surface 212.

Second internal surface 212 may impede the flow of vapor based on firstbaffle 206 and second baffle 210 directing the flow of vapor towardssecond internal surface 212. For example, second top surface 212 b ofsecond internal surface 212 may impede the flow of vapor, therebyreducing a velocity of the flow of vapor in the second direction. Inthis way, some implementations described herein permit a furtherincrease in an amount of time during which the flow of vapor is disposedwithin cooling device 104 and/or is in contact with thermally conductivesurfaces of cooling device 104, thereby permitting further reduction intemperature of the flow of vapor.

Second baffle 210 and sidewall 216 of cooling device 104 may direct theflow of vapor towards internal opening 214 based on the flow of vaporbeing impeded by second internal surface 212. For example, second outersurface 210 d of second baffle 210 and sidewall 216 may direct the flowof vapor towards internal opening 214 based on the flow of vapor beingimpeded by second top surface 212 b of second internal surface 212. Putanother way, the flow of vapor may flow in the second direction betweensecond outer surface 210 d of second baffle 210 and sidewall 216.

Second baffle 210 may taper inwardly from second inlet edge 210 atowards second outlet edge 210 b. In this way, some implementationsdescribed herein permit expansion of vapor as the flow of vapor flowsfrom second internal surface 212 towards internal opening 214. In otherwords, a volumetric area between sidewall 216 and second baffle 210 maybe greater at a position near internal opening 214 than as compared toanother position near second internal surface 212. Put yet another way,a first horizontal distance between sidewall 216 and second outlet edge210 b of second baffle 210 may be greater than a second horizontaldistance between sidewall 216 and second inlet edge 210 a of secondbaffle 210. By permitting expansion of the vapor, some implementationsdescribed herein permit further reduction in temperature of the flow ofvapor.

By permitting expansion of the vapor towards outlet end 204 of secondbaffle 210 with diverging sidewalls, the vapor additionally slows inspeed. This may increase the time that the vapor stays in the coolingchamber (i.e., cooling device 104) and allows for additional time forthermal conduction. Second baffle 210 may be referred to as a diffuser.In other words, second baffle 210 may taper inwardly towards outlet end204 thereby forming a diffuser.

The flow of vapor may flow through internal opening 214 based on beingdirected in the second direction by second baffle 210 and sidewall 216.In this way, the flow of vapor may exit cooling device 104 via outletend 204 and enter mouthpiece 102. A temperature of the vapor when thevapor exits cooling device 104 may be less than a temperature of thevapor when the vapor entered cooling device 104. Thereby, someimplementations described herein may improve usability of vaporizerdevice 100, enhance a user experience associated with vaporizer device100, improve efficacy of vaporizer device 100, and/or the like.

Additionally, in this way, a temperature of the vapor may be reducedwithout requiring water, or another type of cooling material, to be usedto reduce the temperature of the vapor. Thereby, some implementationsdescribed herein improve the design of vaporizer devices, improve a userexperience associated with vaporizer devices, reduce the size ofvaporizer devices, reduce the need for maintenance of vaporizer devices,and/or the like.

While a particular configuration is shown and/or described inassociation with FIGS. 2A and 2B, it should be understood thatimplementations described herein are applicable to other configurationsthan as shown in FIGS. 2A and 2B.

Although FIGS. 2A and 2B show an example cooling device 104, coolingdevice 104 may include additional components, fewer components,different components, or differently arranged components than thosedepicted in FIGS. 2A and 2B. Additionally, or alternatively, two or morecomponents of cooling device 104 may be combined as a single component.

FIG. 3 is a bottom view 300 of cooling device 104. As shown in FIG. 3, afirst, and outermost, concentric circle 316 may correspond to sidewall216 of cooling device 104. As further shown in FIG. 3, a secondconcentric circle 312 a may correspond to second bottom surface 212a ofsecond internal surface 212. As further shown in FIG. 3, a thirdconcentric circle 306 c may correspond to first inner surface 206 c offirst baffle 206. As further shown in FIG. 3, a fourth, and innermost,concentric circle 308 a may correspond to a portion of first bottomsurface 208 a of first internal surface 208 that is visible throughfirst baffle 206.

While FIG. 3 depicts a particular configuration of cooling device 104,it should be understood that other implementations include differentconfigurations than as shown in FIG. 3.

FIG. 4 is a top view 400 of cooling device 104. For example, FIG. 4depicts first top surface 208b of first internal surface 208. As shownin FIG. 4, and as a particular example, cooling device 104 may include afirst internal opening 214 a, a second internal opening 214 b, a thirdinternal opening 214 c, and a fourth internal opening 214 d. Forexample, first internal surface 208 may include a set of internalopenings 214 a-d that permit the flow of vapor to exit cooling device104. It should be understood that other implementations includedifferent numbers of internal openings 214, different shapes of internalopenings 214, and/or different configurations of internal openings 214.

While FIG. 4 depicts a particular configuration, it should be understoodthat other implementations include other configurations than as shown inFIG. 4.

Some implementations described herein reduce a temperature of vaporgenerated by an atomizer device. By implementing a set of baffles and aset of internal surfaces configured to direct the flow vapor through acooling device, some implementations described herein increase an amountof time during which the vapor is disposed within the cooling device,increase exposure of the vapor to thermally conductive surfaces of thecooling device, and/or permit the vapor to expand. In this way, someimplementations described herein increase usability of vaporizerdevices, improve a user experience, increase efficacy of vapor delivery,and/or the like.

The foregoing disclosure provides illustration and description, but itis not intended to be exhaustion or to limit the implementations to theprecise form disclosed. Modifications and variations are possible inlight of the above disclosure or may be acquired from practice of theimplementations.

Even though particular combinations of features are recited in theclaims and/or disclosed in the specification, these combinations are notintended to limit the disclosure of possible implementations. In fact,many of these features may be combined in ways not specifically recitedin the claims and/or disclosed in the specification. Although eachdependent claim listed below may directly depend on only one claim, thedisclosure of possible implementations includes each dependent claim incombination with every other claim in the claim set.

No functionality used herein should be construed as critical oressential unless explicitly described as such. Also, as used herein, thearticles “a” and “an” are intended to include one or more items, and maybe used interchangeably with “one or more.” Furthermore, as used herein,the term “set” is intended to include one or more items (e.g., relateditems, unrelated items, a combination of related and unrelated items,etc.), and may be used interchangeably with “one or more.” Where onlyone item is intended, the term “one” or similar language is used. Also,as used herein, the terms “has,” “have,” “having,” or the like areintended to be open-ended terms. Further, the phrase “based on” isintended to mean “based, at least in part, on” unless explicitly statedotherwise.

What is claimed is:
 1. A device, comprising: an inlet end having a firstopening configured to connect to an atomizer device; an outlet endhaving a second opening configured to permit a user to inhale a vaporgenerated by the atomizer device; a first baffle configured to direct aflow of the vapor towards a first internal surface of the device in afirst direction towards the outlet end and away from the inlet end; thefirst internal surface configured to impede the flow of the vapor in thefirst direction; a second baffle configured to direct the flow of thevapor towards a second internal surface of the device in a seconddirection towards the inlet end and away from the outlet end; and thesecond internal surface configured to impede the flow of the vapor inthe second direction and cause the flow of the vapor to be directedtowards the outlet end of the device.
 2. The device of claim 1, whereinthe second baffle includes a frustoconical shape.
 3. The device of claim1, further comprising an internal opening configured to permit the flowof the vapor to flow through the outlet end of the device.
 4. The deviceof claim 1, further comprising a mouthpiece configured to connect to theoutlet end of the device and to permit the user to inhale the vaporgenerated by the atomizer device.
 5. The device of claim 1, wherein thefirst baffle and the second baffle are configured to direct the flow ofthe vapor between the first baffle and the second baffle in the seconddirection.
 6. The device of claim 1, further comprising the atomizerdevice.
 7. The device of claim 1, wherein the second baffle tapersinwardly in the first direction forming a diffuser.
 8. A device,comprising: an inlet end having a first opening, a flow of a vapor,generated by an atomizer device, to enter the inlet end of the devicevia the first opening; a first baffle configured to direct the flow ofthe vapor towards a first internal surface of the device in a firstdirection towards an outlet end of the device and away from the inletend of the device, the flow of the vapor to be directed by the firstbaffle based on entering the inlet end of the device; the first internalsurface configured to impede the flow of the vapor in the firstdirection, the flow of the vapor to be impeded by the first internalsurface based on being directed by the first baffle; a second baffleconfigured to direct the flow of the vapor in a second direction towardsthe inlet end of the device and away from the outlet end of the device,the flow of the vapor to be directed by the second baffle based on beingimpeded by the first internal surface; a second internal surfaceconfigured to impede the flow of the vapor in the second direction, theflow of the vapor to be impeded by the second internal surface of thedevice based on being directed by the second baffle, and the flow of thevapor to be directed in the first direction based on being impeded bythe second internal surface; and the outlet end having a second opening,the flow of the vapor to exit the outlet end of the device via thesecond opening based on being directed in the first direction.
 9. Thedevice of claim 8, further comprising a mouthpiece configured to connectto the outlet end of the device.
 10. The device of claim 8, furthercomprising the atomizer device configured to connect to the inlet end ofthe device.
 11. The device of claim 8, wherein a first surface of thesecond baffle is configured to direct the flow of the vapor in the firstdirection, and a second surface of the second baffle is configured todirect the flow of the vapor in the second direction.
 12. The device ofclaim 8, wherein the first baffle and the second baffle are configuredto direct the flow of the vapor in the second direction between an outersurface of the first baffle and an inner surface of the second baffle.13. The device of claim 8, wherein the second baffle is configured todirect the flow of the vapor in the first direction between a sidewallof the device and an outer surface of the second baffle.
 14. The deviceof claim 8, wherein a first distance between a sidewall of the deviceand a first end of the second baffle is greater than a second distancebetween the sidewall of the device and a second end of the secondbaffle, the second end of the second baffle being closer to the outletend of the device than the inlet end of the device.
 15. A cap for avaporizer device, comprising: an inlet configured to permit a flow of avapor, generated by the vaporizer device, to enter the cap; a set ofinternal surfaces configured to impede the flow of the vapor; a set ofbaffles configured to direct the flow of the vapor towards the set ofinternal surfaces and towards an outlet of the cap; and the outletconfigured to permit the flow of the vapor to exit the cap.
 16. The capfor the vaporizer device of claim 15, further comprising a mouthpiececonfigured to permit a user to inhale the vapor.
 17. The cap for thevaporizer device of claim 15, further comprising the vaporizer device.18. The cap for the vaporizer device of claim 15, wherein a firstinternal surface, of the set of internal surfaces, is configured toimpede the flow of the vapor in a first direction towards the outlet andaway from the inlet.
 19. The cap for the vaporizer device of claim 15,wherein a first inner surface of a first baffle, of the set of baffles,is configured to direct the flow of the vapor towards the outlet of thecap; a first outer surface of the first baffle, of the set of baffles,and a second inner surface of a second baffle, of the set of baffles,are configured to direct the flow of the vapor towards the inlet of thecap; and a second outer surface of the second baffle, of the set ofbaffles, and a sidewall of the cap are configured to direct the flow ofthe vapor towards the outlet of the cap.
 20. The cap for the vaporizerdevice of claim 15, wherein a first internal surface, of the set ofinternal surfaces, includes a set of openings that is configured topermit the flow of the vapor to exit the outlet of the cap.